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2.1 FICK’S LAW OF DIFFUSION 
2.1.1 First law of diffusion (Steady state Law) Adolf Fick (1955) first described the molecular diffusion in an isothermal, isobaric binary system of components A and B
[1-3]. According to his idea of molecular diffusion, the molar flux of a species relative to an observer moving with molar average velocity is proportional to the concentration gradient in a certain direction.
Fick’s Law Of Diffusion | Mass Transfer - Chemical Engineering                                                     (2.1)
Or
Fick’s Law Of Diffusion | Mass Transfer - Chemical Engineering                                           (2.2)
Where, JA is the molar flux of component A in the Z direction. CA is the concentration of A and Z is the distance of diffusion. The proportionality constant, DAB is the diffusion coefficient of the molecule A in B. This is valid only at steady state condition of diffusion. The Equation (2.2) is called Fick’s first law of diffusion. If the concentration gradient is expressed as the gradient of mole fraction and in three dimensional cases, the molar flux can be expressed as
Fick’s Law Of Diffusion | Mass Transfer - Chemical Engineering                 (2.3) 

2.1.2 Prove that mutual diffusivities of species A and B are equal if gas mixture is ideal when total pressure is constant.
Substituting the Equation (2.2) for JA into Equation (1.21) in module 1, the molar flux with negligible bulk movement of component A of the binary gas mixture can be represented as
Fick’s Law Of Diffusion | Mass Transfer - Chemical Engineering                      (2.4)
Similarly for component B, it can be written as
Fick’s Law Of Diffusion | Mass Transfer - Chemical Engineering                         (2.5)
Since NA + NB =N and yA + yB = 1, addition of Equations (2.4) and (2.5) gives,
Fick’s Law Of Diffusion | Mass Transfer - Chemical Engineering                         (2.6)
Differentiation of the equality, yA+ yB = 1 with respect to Z, gives
Fick’s Law Of Diffusion | Mass Transfer - Chemical Engineering                                              (2.7)
Substituting the Equation (2.7) into Equation (2.6) one can get
DAB = DBA                                                  (2.8)
From Equation (2.8) it is seen that for a binary gas mixture, the diffusivity of A in B equals the diffusivity of B in A.

2.1.3 Unsteady state Diffusion
If the change of concentration of a component A of the diffusive constituents in a mixture occurs over a time at a point, the Fick’s law of diffusion at unsteady state condition can be expressed for Z-direction as
Fick’s Law Of Diffusion | Mass Transfer - Chemical Engineering                                  (2.9)
Both the diffusive and non-diffusive constituents affect the rate of unsteady state diffusion. The diffusivity at unsteady state condition can be expressed in terms of activation energy and the temperature as
Fick’s Law Of Diffusion | Mass Transfer - Chemical Engineering                          (2.10)
The activation energy (ED) for the diffusion decreases the rate of diffusion whereas temperature increases the diffusion rate.

The document Fick’s Law Of Diffusion | Mass Transfer - Chemical Engineering is a part of the Chemical Engineering Course Mass Transfer.
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FAQs on Fick’s Law Of Diffusion - Mass Transfer - Chemical Engineering

1. What is Fick's law of diffusion?
Ans. Fick's law of diffusion is a fundamental principle in chemical engineering that describes the rate at which a substance diffuses through a medium. It states that the flux of a substance is directly proportional to the concentration gradient and the diffusion coefficient, and inversely proportional to the thickness of the medium.
2. How is Fick's law applied in chemical engineering?
Ans. Fick's law of diffusion is widely used in chemical engineering to analyze and predict the transport of substances in various processes. It helps engineers understand how molecules move through different materials, such as gases through membranes or liquids through porous media. By applying Fick's law, engineers can optimize processes involving diffusion, such as designing efficient separation processes or developing drug delivery systems.
3. What are the key factors that affect diffusion according to Fick's law?
Ans. According to Fick's law of diffusion, there are three key factors that influence the rate of diffusion: the concentration gradient, the diffusion coefficient, and the thickness of the medium. A larger concentration gradient (difference in concentration between two points) will lead to a higher diffusion rate. A higher diffusion coefficient, which depends on the properties of the substance and the medium, will also increase the rate of diffusion. Conversely, a thicker medium will impede diffusion and result in a slower diffusion rate.
4. Can Fick's law be applied to both liquids and gases?
Ans. Yes, Fick's law of diffusion can be applied to both liquids and gases. It is a general principle that describes the movement of substances through a medium, regardless of whether the substance is in a liquid or gaseous state. The concentration gradient, diffusion coefficient, and medium thickness are the key factors that determine the rate of diffusion in both liquids and gases.
5. How does Fick's law of diffusion relate to mass transfer in chemical engineering?
Ans. Fick's law of diffusion is closely related to mass transfer in chemical engineering. Mass transfer refers to the movement of substances from one phase to another, such as from a gas phase to a liquid phase or vice versa. Diffusion is one of the mechanisms responsible for mass transfer, and Fick's law provides a quantitative description of how substances diffuse through a medium. By understanding and applying Fick's law, chemical engineers can analyze and optimize mass transfer processes, such as distillation, absorption, and extraction, in various industries.
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